Vanadium/Titania Catalyst Comprising Natural Manganese Ore for Removing Nitrogen Oxides and Dioxin in Wide Operating Temperature Range and Method of Using the Same

ABSTRACT

Disclosed is a vanadium/titania-based catalyst including natural manganese ore for removing nitrogen oxides and dioxin in a wide operating temperature range and a method of using the same. Specifically, this invention pertains to a vanadium/titania (V/TiO2)-based catalyst including natural manganese ore for removing nitrogen oxides and dioxin in a wide operating temperature range, in which the WTiO2 catalyst for selective catalytic reduction of nitrogen oxides and removal of dioxin contained in flue gas includes 5-30 wt % of natural manganese ore, thus exhibiting excellent activity of removing nitrogen oxides even in the low temperature range and of removing dioxin at the same time, and to a method of using the same. The catalyst of this invention has good thermal stability and thus can simultaneously manifest nitrogen oxides removal performance and dioxin removal performance superior to conventional vanadium/titania catalysts in a wide temperature range (150˜450° C.) including not only a high temperature range but also a low temperature range. As well, since unreacted ammonia emissions can be reduced, the formation of an ammonium salt is prevented and ammonium nitrate is decomposed at low temperatures, thus solving the problems of inactivation of the catalyst due to catalytic poisoning and of a shortened lifetime thereof, leading to economic benefits.

TECHNICAL FIELD

The present invention relates to a vanadium/titania-based (V/TiO₂)catalysts comprising natural manganese ore (NMO) for removing nitrogenoxides and dioxin in a wide operating temperature range and a method ofusing the same. More particularly, the present invention relates to aV/TiO₂ catalyst comprising NMO for removal of nitrogen oxides and dioxinin a wide operating temperature range, in which the V/TiO₂ catalyst ismixed with NMO to increase the activity of removal of nitrogen oxides inthe low temperature range so as to effectively remove nitrogen oxidesand dioxin not only at high temperatures but also at low temperatures,and to a method of using the same.

BACKGROUND ART

Generally, fossil fuels are burned to produce energy for thermal powerplants and industrial complexes, and also are burned in incinerators todecrease the volume of waste and to increase the chemical stabilitythereof. In such cases, various hazardous flue gases, such as carbondioxide, sulfur dioxide (SO₂), nitrogen oxides (NO_(x)), dioxins,volatile organic compounds, heavy metals, etc., are produced. Amongthese flue gases, nitrogen oxides function as an environmentalpollutant, which is harmful to the human body and causes photochemicalsmog or decreases a visibility distance. Nitrogen oxides are composedmainly of nitrogen monoxide (NO) and nitrogen dioxide (NO₂), in which NOconstitutes 95% of total nitrogen oxides. As such, nitrogen oxides areclassified into thermal NO_(x), prompt NO_(x), and fuel NO_(x),depending on the formation procedure thereof.

In the case of a combustion boiler using fossil fuel, the fuel ispre-treated or combustion conditions are improved to reduce the emissionof nitrogen oxides. However, in the interest of economy and efficiency,a combustion post-treatment process requiring an additional treatmentprocedure after the combustion is effective. Such combustionpost-treatment includes catalytic cracking, selective catalyticreduction (SCR), selective non-catalytic reduction (SNCR), non-selectivecatalytic reduction (NSCR), and plasma treatment. Presently, SCR usingan ammonia reducing agent is known to be the most effective.

Through ammonia-based SCR, on the surface of a denitrification catalyst,reactions take place as represented by Reactions 1 to 5 below:

4NO+4NH₃+O₂→4N₂+6H₂O  Reaction 1

2NO₂+4NH₃+O₂→3N₂+6H₂O  Reaction 2

6NO+4NH₃→5N₂+6H₂O  Reaction 3

6NO₂+8NH₃→7N₂+12H₂O  Reaction 4

NO+NO₂+2NH₃→2N₂+3H₂O  Reaction 5

Although the denitrification catalyst useful in the ammonia-based SCRmay be variously prepared, a denitrification catalyst comprising atitania support, vanadium, and optionally tungsten exhibits the greatestefficiency at present and thus has been commercialized and is used allover the world. The V/TiO₂ catalyst typically has high activity at300˜400° C., but is decreased with respect to nitrogen oxides removalefficiency due to low activation energy at temperatures lower than theabove temperature. On the other hand, at temperatures higher than theabove temperature, the ammonia reducing agent is oxidized, thus thestoichiometric ratio of the reaction becomes inappropriate, undesirablydecreasing the efficiency. Further, the thermal fatigue of the catalystis increased, leading to a shortened catalyst lifetime.

In the flue gas, water and sulfur oxides are generally present. Suchmaterials function to produce an ammonium salt on the denitrificationcatalyst, lowering the activity of the catalyst. The reactions poisoningthe catalyst progress according to Reactions 6 to 8 below:

2SO₂+O₂→2SO₃  Reaction 6

NH₃+SO₃+H₂O→NH₄HSO₄  Reaction 7

SO₃+H₂O→H₂SO₄  Reaction 8

Sulfur trioxide produced in Reaction 6 is formed into sulfate inReaction 7, which is not decomposed on the surface of the catalyst butremains thereon, thus poisoning the catalyst. In addition, sulfuric acidproduced in Reaction 8 corrodes a catalyst bed and equipment in thesubsequent stage of the system.

Because the production of sulfur trioxide according to Reaction 6actively proceeds at high temperatures, the development of a catalystcapable of realizing excellent SCR of nitrogen oxides at lowtemperatures has been required to minimize the above production so as toreduce the formation of sulfate and sulfuric acid in Reactions 7 and 8.

In addition, another important cause of inactivation of SCR in the lowtemperature range is ammonium nitrate formed at a low temperature of200° C. or less through the reactions represented by Reactions 9 and 10below:

2NH₃+2NO₂→NH₄NO₃+N₂+H₂O  Reaction 9

2NH₃+H₂O+2NO₂→NH₄NO₃+NH₄NO₂  Reaction 10

Ammonium nitrite (NH₄NO₂) produced in Reaction 9 is very unstable, andthus is decomposed at 60° C. or higher, not causing a large problem.However, ammonium nitrate (NH₄NO₃) produced in Reaction 10 must beconsidered because it has a melting point of 170° C. Reactions 11 to 13below show the decomposition of solid ammonium nitrate:

NH₄NO₃(s)

NH₃+HNO₃  Reaction 11

NH₄NO₃(s)→N₂O+2H₂O  Reaction 12

2NH₄NO₃(s)→2N₂+O₂+4H₂O  Reaction 13

Generally, for efficient SCR in the presence of the V/TiO₂ catalyst,since the temperature of the flue gas should be maintained high in therange of 300˜400° C., a process capable of supporting SCR is limited inthe flue gas disposal process. For example, in the case of thermal powerplants using coal or oil, the temperature after the economizer of aboiler may be a high temperature of about 350° C., and thus the SCRsystem can be installed. However, due to dust and/or sulfur dioxidehaving high concentration, the active sites of the denitrificationcatalyst may be lessened, and also the denitrification catalyst may beabraded. Further, ammonium sulfate may be formed in equipment in thesubsequent stage of the system due to the oxidation of sulfur trioxide(SO₃), leading to corrosion of such equipment. Accordingly, methods ofinstalling the SCR system downstream of a dust collector and adesulfurization system have been proposed. However, because thetemperature of the flue gas decreases considerably while it passesthrough the dust collector and desulfurization system, there is the needfor a denitrification catalyst suitable for use in SCR even at such lowtemperatures. Particularly, in the system for wet flue gasdesulfurization (WFGD), no SCR is expected because the temperature ofthe flue gas is reduced to 100° C. or less, thus an additional reheatingsystem is required. In order to increase the actual temperature of theflue gas by about 100° C., a large amount of power, corresponding toabout 5˜10% of the total power capacity of the power plant, is known tobe consumed. In this way, flue gas denitrification using a conventionalcommercially available V/TiO₂ catalyst is a process that consumes alarge amount of energy depending on the high-temperature activity of adenitrification catalyst. Moreover, with the intention of obtainingpredetermined efficiency at low temperatures using the high-temperaturecatalyst, the catalyst should be provided in a larger amount. That is,when the amount of the catalyst is increased, not only the catalyst costbut also the costs related to a catalyst reactor, a duct, the amount ofreducing agent and the reducing agent supply are increased, and as well,the pressure loss of the flue gas is increased, negatively affecting thetotal system.

The high-temperature operation facilitates thermal fatigue of thecatalyst bed, undesirably shortening the lifetime of the catalyst.Further, since sulfur dioxide is highly oxidized ammonium sulfate,acting as a cause of corrosion, is formed in equipment in the subsequentstage of the system for SCR. In addition, even though ammonium nitratein addition to ammonium sulfate is formed on the surface of thedenitrification catalyst, a denitrification catalyst capable ofdecomposing such materials at temperatures lower than a conventionaltemperature through the catalytic cracking reaction is required. Suchproperties depend on the excellent oxidation and/or reduction of thedenitrification catalyst. That is to say, in order to solve problemsrelated to economic benefits, inhibition of catalytic poisoning materialand extension of lifetime of the catalyst, a low-temperaturedenitrification catalyst having higher denitrification performance evenat a low temperature of 250° C. or less is required, unlike when usingthe conventional V/TiO₂ catalyst.

Meanwhile, manganese oxides of NMO function to easily induce thecirculation of oxidation and reduction, and the oxidation state of themanganese ion thereof is readily changed, and thus the NMO may beapplied to a variety of fields such as denitrification, ammoniaoxidation, VOC removal, CO oxidation, etc. In addition, manganese oxidesare known to have very high activity upon oxidation, and such activitymay be easily understood through the change of oxidation state ofmanganese oxides in the gas-solid reaction. Recently, it has beenreported that pure MnO₂ and manganese oxide supported on alumina exhibitvery high activity upon the SCR reaction using ammonia as a reducingagent in the temperature range of 380˜570 K (L. Singoredjo, R. Kover, F.Kapteijn and J. Moulijn, Applied Catalysis B: Environ., 1, 297 (1992))

In regard to conventional NMO techniques for removing nitrogen oxides,Korean Patent Laid-open Publication No. 1998-086887 discloses the use ofNMO to remove nitrogen oxides at low temperatures of 130˜250° C. and toreduce unreacted ammonia emission through oxidation. According to KoreanPatent Laid-open Publication No. 2002-0051885, NMO is heat treated at300˜400° C., or supported with one, two or more metal oxides selectedfrom among tungsten (W), iron (Fe), copper (Cu), vanadium (V), zirconium(Zr), silver (Ag), cerium (Ce), platinum (Pt), and palladium (Pd) and isthen heat treated at 300˜400° C. to remove nitrogen oxides. In addition,according to Korean Patent Laid-open Publication No. 2000-0031268,sulfur oxides and nitrogen oxides may be simultaneously removed using acontinuous fluidized-bed reactor in the presence of NMO (pyrolusite,β-MnO₂). Further, according to US Patent Application No. 732082, withthe aim of realizing the low-temperature activity of a V/TiO₂ catalyst,based on the weight of supported vanadium, the sum of V⁺⁴ and V⁺³,represented by V^(+x) (x≦4), should be 34 atoms/cm³·wt % or more, andthe sum of Ti⁺³ and Ti⁺², represented by Ti^(+y) (y≦3), should be 415atoms/cm³·wt % or more.

The emission source, such as an incineration facility, discharges alarge amount of dioxins, in addition to nitrogen oxides, dioxins beingthe most poisonous material among materials known to date and havingtoxicity ten thousand times greater than the toxicity of potassiumcyanide. Furthermore, dioxin is nobiodegradable, stable even at 700° C.,and accumulates in the body and thus negatively affects the human body,causing side effects too numerous to be completely listed, and includingcancers, reproduction toxicity, malformation, liver toxicity, thyroidgland disorders, cardiac disorders, etc.

Accordingly, with the aim of reducing the emission of such dioxins,there are exemplified control methods before incineration, includingpreliminary removal of a dioxin precursor and uniform supply of waste,control methods during incineration, including suitable operatingtemperature and resident time, combustion air and mixing, minimizationof fly ash particles and control of temperature of flue gas, and controlmethods after incineration, including a combination of a wet washer, adry washer, an activated carbon sprayer, a dust collector, SNCR, and SCRdevices. In the control method before the incineration, the compositionof waste is analyzed, relationships with harmful material generatedafter combustion are investigated, the type of waste functioning as amain pollutant is preliminarily sorted, the amount and size of waste tobe added to the incinerator are maintained constant, and thecomposition, heat value, water content, and volatile component contentare made constant, thus uniformly maintaining the combustion environmentin the furnace.

The control method during the incineration controls the 3 Ts, that is,

1) temperature of 850° C. or more

2) time of 2 sec or longer

3) turbulence due to the geometry of the incinerator and second airinjection.

That is, such combustion conditions are efficiently controlled andmaintained, and therefore non-burned carbon or hydrocarbon in thecombustion gas, in particular, a precursor capable of being easilyconverted into dioxins, for example, chlorobenzene or polychlorinatedbiphenyl, may be produced in a smaller amount.

In the control methods after the incineration, a method of adsorbing apollutant using an activated carbon and then continuously passing itthrough an oxidation catalyst bed to control it is most effective.However, due to the problems with techniques and performance of thecatalyst bed, the control of dioxin is mainly dependent on adsorptionusing an adsorbent, such as activated carbon and calcium hydroxide.Moreover, the reproduction or disposal of the adsorbent having dioxinadsorbed thereon is technically difficult, and thus an economic burdenmay be imposed. That is, presently available methods of adsorbing dioxinin the flue gas using activated carbon suffer because the activatedcarbon on which dioxin is adsorbed is difficult to reproduce or dispose,and thus economic benefits are negated.

Typically, as a catalyst for the oxidation of dioxin as a volatilehalogen organic material, a catalyst obtained by adding WO₃ or MoO₃ toV₂O₅/TiO₂, such as an SCR catalyst, is useful although the amountthereof must be varied for optimal activity. Like nitrogen oxides,dioxins need to be removed at temperatures as low as possible. This isbecause requiring less energy for heating the combustion flue gas iseconomically preferable, and materials decomposed by the catalyst may beundesirably re-synthesized at 205° C. or higher in the presence of oxideof metal (Cu, Fe, etc.).

DISCLOSURE Technical Problem

Leading to the present invention, intensive and thorough research intothe effective removal of dioxin, as well as nitrogen oxides through SCRusing an ammonia reducing agent not only at low temperatures of 250° C.or less but also at high temperatures of 300˜400° C., carried out by thepresent inventors, aiming to overcome the problems encountered in theprior art, resulted in the finding that a predetermined amount of NMOcan be added to a V/TiO₂ catalyst to form a novel composite oxide, whichthus can exhibit excellent denitrification performance not only at hightemperatures but also at low temperatures and which furthermore canremove dioxin.

Accordingly, an object of the present invention is to provide avanadium/titania catalyst comprising NMO for removing nitrogen oxidesand dioxin in a wide operating temperature range, capable of exhibitingexcellent activity of removal of nitrogen oxides and dioxin not only athigh temperatures but also at low temperatures.

Another object of the present invention is to provide a method of SCR ofnitrogen oxides and removal of dioxin in a wide temperature range.

Technical Solution

In order to accomplish the above objects, the present invention providesa V/TiO₂ catalyst comprising NMO for removing nitrogen oxides and dioxinin a wide operating temperature range, wherein the V/TiO₂ catalystsuitable for use in SCR of nitrogen oxides and removal of dioxincontained in flue gas comprises 5˜30 wt % of the NMO.

In addition, the present invention provides a method of SCR of nitrogenoxides and removal of dioxin, contained in flue gas, which is conductedat 150˜450° C. at a gas hourly space velocity (GHSV) of 1000˜60000 hr⁻¹in the presence of the catalyst mentioned above.

DESCRIPTION OF DRAWINGS

FIG. 1 is a view schematically showing the structure of a device forevaluating the performance of the catalyst of the present invention onSCR of nitrogen oxides and on removal of dioxin;

FIG. 2 is a graph showing the nitrogen oxides removal performance of thecatalyst (NMO+V/TiO₂ (N)) containing no tungsten of the presentinvention, NMO, and a V/TiO₂ (N) catalyst, varying depending on thereaction temperature;

FIG. 3 is a graph showing the emission of unreacted ammonia of thecatalyst (NMO+V/TiO₂ (N)) containing no tungsten of the presentinvention, the NMO, and the V/TiO₂(N) catalyst, varying depending on thereaction temperature upon removal of nitrogen oxides;

FIG. 4 is a graph showing the nitrogen oxides removal performance of thecatalyst (NMO+V/TiO₂ (W)) containing tungsten of the present invention,the NMO, and the V/TiO₂(W) catalyst, varying depending on the reactiontemperature;

FIG. 5 is a graph showing the emission of unreacted ammonia of thecatalyst (NMO+V/TiO₂ (W)) containing tungsten of the present invention,the NMO, and the V/TiO₂(W) catalyst, varying depending on the reactiontemperature upon the removal of nitrogen oxides;

FIG. 6 is a graph showing the results of an oxygen shutting-off test forthe NMO+V/TiO₂ catalyst and the V/TiO₂ catalyst;

FIG. 7 is a graph showing the results of a catalyst re-oxidation testfor the NMO+V/TiO₂ catalyst and the V/TiO₂ catalyst;

FIG. 8 is a graph showing the results of detection of the amount ofnitrogen monoxide decomposed through TPO (Temperature ProgrammedProgram) depending on temperature, in order to deduce the decompositionproperty of ammonium nitrate on the NMO+V/TiO₂ catalyst of the presentinvention, the NMO, and the V/TiO₂ catalyst; and

FIG. 9 is a graph showing the performance of the NMO+V/TiO₂ catalyst ofthe present invention on the removal of dioxin and/or nitrogen oxides.

BEST MODE

Hereinafter, a detailed description will be given of the presentinvention.

As mentioned above, the catalyst of the present invention (NMO+V/TiO₂catalyst) includes NMO and thus exhibits excellent activity on the SCRof nitrogen oxides and on removal of dioxin not only at hightemperatures but also at low temperatures.

The NMO is present in various forms, such as pyrolusite, psilomelane,manganite, braunite, or hausmanite, as shown in Table 1 below.

TABLE 1 Type Composition Specific Gravity Mn (%) Pyrolusite MnO₂ 4.863.2 Psilomelane 3.7~4.7 45~60 Manganite Mn₂O₃•H₂O 4.2~4.4 62.4 Braunite3Mn₂O₃•MnSiO₃ 4.8 62 Hausmanite Mn₃O₄ 4.8 72 Rhodochrosite MnCO₃ 47 orDialogite Rhodonite MnSiO₃ 42 Bementite Hydrated Silicate 31

The NMO mainly exists in the form of pyrolusite and psilomelane. The NMOused in the present invention is pyrolusite, in which manganese oxide ismainly composed of β-MnO₂, and the physicochemical properties thereofare shown in Table 2 below.

TABLE 2 (1) Chemical Analysis (wt %) Constit- O₂ relative uent Mn SiO₂Al₂O₃ Fe CaO MgO to Mn and Fe Wt % 51.85 3.13 2.51 3.86 0.11 0.25 38.33(2) Physical Properties Average Particle Size (mm) 0.359 Density (kg/m³)3980 Pore Volume (cm³/g) 0.0369 (5~3000 Å) Specific Surface Area (m²/g)20.0

As shown in Table 2, the NMO, comprising various metal oxides, Mn, andFe, may be used as the catalyst for SCR, and has excellent nitrogenoxides conversion at a low temperature (about 150° C.).

The NMO of the present invention is prepared through the followingprocedure. According to the present invention, NMO is dried andcalcined. As such, the drying process is preferably conducted at100˜110° C. for 4˜10 hours, and the calcination process is preferablycarried out at 100˜500° C. for 3˜5 hours in an air atmosphere.Subsequently, the dried and calcined NMO powder is compressed at apressure of 4,000˜6,000 psi to form a pellet, which is then milled to anaverage particle size of 300˜425 μm.

The V/TiO₂ catalyst of the present invention is formed by supportingvanadium on titania (TiO₂). The titania support of the present inventionshould be used in supporting the SCR catalyst. That is, since titaniafor paint or an optical catalyst is unsuitable for use in the presentinvention in consideration of performance and price, titania produced asa catalyst support is employed. The preferred physical properties oftitania, usable as the support of the present invention, are shown inTable 3 below, but the present invention is not limited thereto.

In Table 3 below, tungsten is a co-catalyst which is selectively addedto the SCR catalyst, and may be added in order to increase thermaldurability and resistance to SO₂. However, tungsten does not greatlyaffect the nitrogen oxides removal performance of the catalyst of thepresent invention.

When using tungsten, titania may be first supported with tungsten andcalcined to form a mixture support which is then supported withvanadium, or titania may be simultaneously supported with tungsten andvanadium. During the calcination process, tungsten is converted intooxide, and the amount of tungsten oxides is about 0˜15 wt %, andpreferably, 5˜10 wt %, based on the weight of titania.

TABLE 3 TiO₂ Amount 85~100 wt % Particle Size 15~40 nm Specific Surface50~120 m²/g Anatase Amount 75~100 wt % Tungsten Oxide Amount 0~10 wt %Average Pore Volume 0.1~0.5 cm³/g

Examples of the vanadium precursor of the present invention include, butare not particularly limited to, ammonium metavanadate (NH₄VO₃),vanadium oxytrichloride (VOCl₃), etc. According to the presentinvention, the catalyst is prepared through a wet impregnation processusing a solution of quantified ammonium metavanadate (NH₄VO₃) dissolvedin distilled water and oxalic acid ((COOH)₂). Specifically, the amountof vanadium relative to titania is calculated according to the desiredcomposition ratio. Thus, in consideration of economic benefits,performance and SO₂ oxidation performance, vanadium is preferably addedin an amount of 0.5˜10 wt % based on the element of the support. Thevanadium precursor is dissolved in a calculated amount in distilledwater heated to 50˜70° C. In this case, when ammonium metavanadate isused as the precursor, since it has very low solubility, solubilitythereof is increased in a manner such that the aqueous solution iscontinuously mixed with oxalic acid while being slowly stirred to attaina pH of 2.5. The resulting solution has a light orange color.Subsequently, the solution is mixed with the calculated amount oftitania while being continuously stirred, and the mixture slurry thusobtained is completely mixed, and then water is removed.

According to the present invention, in order to prepare the catalyst,the slurry is stirred for 1 hour or longer, after which water isevaporated at 70° C. using a rotary vacuum evaporator. Subsequently, theresulting product is further dried at 100˜110° C. for 24 hours, heatedto 300˜500° C. at a rate of 5˜20° C./min, and calcined at thattemperature for 1˜10 hours in an air atmosphere, yielding the catalyst.The drying oven and the calcination furnace used in the presentinvention are not particularly limited with respect to the formsthereof, and may include commercially available ones.

Then, NMO and V/TiO₂ thus prepared are mixed at a predetermined weightratio and are wet mixed using distilled water, in which NMO is mixedwith V/TiO₂ in an amount of 5˜30 wt %. In the present invention, aball-milling process is used to realize high dispersion, but the presentinvention is not limited thereto. When the amount of NMO is less than 5wt %, an increase in nitrogen oxides removal performance at lowtemperatures becomes insignificant. On the other hand, when the amountexceeds 30 wt %, nitrogen oxides removal performance is somewhatdecreased. The mixed catalyst is dried at 80˜110° C. for 2˜24 hours andthen calcined at 100˜500° C. for 2˜6 hours in an air atmosphere. In sucha case, in the mixed catalyst, a chemical reaction progresses betweenNMO and V/TiO₂, and thus a chemical structure different from thesurfaces of the catalysts before they are mixed results, therebyexhibiting denitrification properties in a wide temperature range. WhenNMO and V/TiO₂ are mixed to a high degree of dispersion through a wetmixing process, dried, and then calcined at a high temperature, latticeoxygen migration to the contact surface between NMO and V/TiO₂ isinduced by high heat energy supplied during the calcination process suchthat the different structures between the two catalysts are reorganizedinto a novel stable structure. That is, in the NMO composed of MnO₂ andin the V/TiO₂ catalyst composed of V₂O₅ and TiO₂, the number of latticeoxygen atoms surrounding the metal atom varies due to the differentoxidation value of each metal atom. The lattice oxygen migration iscaused by the difference between oxygen affinities of metal oxidesduring the high-temperature calcination process. The resulting mixedcatalyst has a structure different from the original structure of thecatalyst. Therefore, the NMO+V/TiO₂ catalyst of the present invention isnot a simple mixture, but a catalyst having a novel structure.

The catalyst of the present invention thus prepared may be used byapplying it on a metal plate, metal fibers, a ceramic filter or ahoneycombed structure or by adding a small amount of binder thereto andthen extruding it in the form of a particle or monolith. As such, thecatalyst is uniformly milled to a particle size of about 1˜10 μm toapply or extrude it, such application and extrusion processes beingwidely known in the art. Further, the mixed catalyst of the presentinvention may be used by applying it on an air preheater, or on all ofthe tubes, the ducts, and/or the wall of a boiler.

The process of removing nitrogen oxides using the catalyst of thepresent invention is conducted at 150˜450° C., and preferably 200˜400°C., at GHSV of about 1,000˜60,000 hr⁻¹, and preferably 5,000˜15,000hr⁻¹, in the presence of the catalyst of the present invention.

In this case, for the SCR of nitrogen oxides, it is preferred that theammonia reducing agent be supplied at a molar ratio of NH₃/NO_(x) of0.6˜1.2. If the molar ratio is less than 0.6, nitrogen oxides removalefficiency is decreased due to the lack of the reducing agent. On theother hand, if the molar ratio exceeds 1.2, unreacted ammonia may beemitted. Particularly, in the case where nitrogen oxides are removedfrom flue gas containing sulfur oxides such as sulfur dioxide, unreactedammonia emission should be maximally reduced so as to effectivelyprevent the poisoning of the catalyst attributable to the production ofammonium sulfate.

The reason why the NMO+V/TiO₂ catalyst of the present invention exhibitshigh nitrogen oxides removal efficiency not only at high temperaturesbut also at low temperatures is because oxidation of ammonia isprevented and the surface structure of the catalyst is changed throughthe mixing of two materials, thus manifesting a synergetic effect. Whenthe NMO is used alone as the catalyst of the SCR reaction, ammonia addedas the reducing agent may be oxidized by the high oxidation capabilityof the NMO at a high temperature of 300° C. In this way, the oxidationof ammonia causes the production of NO or NO₂ which is desirably removedthrough reduction. Further, although ammonia is adsorbed on the surfaceof the catalyst to exhibit a reduction function, the amount thereof isinsufficient due to oxidation, and thus the SCR reaction does notproceed any further. As a result, nitrogen oxide removal efficiency maybe decreased. Accordingly, the NMO may be used alone as the SCR catalystonly in the temperature range of 200° C. or less. That is, the NMOhaving high oxidation capability is impossible to use as the SCRcatalyst in a wide temperature range including low temperatures of 250°C. or less and high temperatures of 300° C. or more.

Therefore, as in the present invention, when the catalyst is prepared bymixing the NMO with V/TiO₂, the above problems may be overcome. That is,the ammonia oxidation of the NMO at high temperatures may be preventedby the use of the V/TiO₂ catalyst, such that the usability of ammonia asa reducing agent increases. In this way, the reason why the catalyst ofthe present invention has higher activity than a conventional V/TiO₂catalyst not only at high temperatures but also at low temperatures isbelieved to be because the properties of the catalyst are modifiedthrough the mixing with the NMO. In order to evaluate the properties ofthe catalyst of the present invention, an oxygen shutting-off test wasconducted. The SCR reaction is one of oxidation/reduction reaction. Theoxidation/reduction reaction takes place through electron transferbetween the catalyst and the chemical species, and efficient electrontransfer results in high activity. In an actual reaction, electrontransfer is realized through the migration of oxygen. As such, latticeoxygen of the catalyst functions as an electron acceptor or an electrondonor. Hence, lattice oxygen of the catalyst is regarded as a veryimportant factor determining the activity of the catalyst. The oxygenshutting-off test for evaluating the lattice oxygen of the catalyst isperformed as follows. That is, 200 ppm NO, 200 ppm NH₃ and 15% oxygenare added to each of the catalyst of the present invention and theconventional V/TiO₂ catalyst at a predetermined temperature (200° C. inthe present invention), and the supply of oxygen is immediately blockedin the course of stably performing the SCR reaction, and thus, 1 hourafter blocking the supply of oxygen, the supply of oxygen is immediatelyresumed to detect the emission concentration of NO. When the supply ofoxygen is blocked, the SCR reaction takes place using lattice oxygen ofthe catalyst. That is, after blocking the supply of oxygen, since theSCR reaction proceeds for a predetermined period of time using suchlattice oxygen, nitrogen oxides removal efficiency is not drasticallydecreased. The lattice oxygen of the catalyst is supplied as long as itexhibits nitrogen oxides removal efficiency. The period of time duringwhich nitrogen oxides removal efficiency is exhibited is proportional tothe amount of lattice oxygen of the catalyst.

The denitrification catalyst of the present invention functions toexhibit the ability to supply the lattice oxygen of the catalyst, thatis, to increase the oxidation capability as well as the reducibility ofthe lattice oxygen. Such properties can be confirmed through a catalystre-oxidation test. Each of the catalyst of the present invention and theconventional denitrification catalyst is loaded in a predeterminedamount, and is then allowed to react with 0.5% NH₃ at 400° C. for 30 minto reduce it, after which the reduced catalyst is cooled to roomtemperature and then added with 1% O₂. When the signal of oxygen reachesa steady state, the reduced catalyst is re-oxidized using gaseous oxygenwhile being heated at a rate of 10° C./min, during which the amount ofoxygen consumed is measured using a Quadrupole mass spectrometer(Prisma™ QMI 422, Pfeiffer Vacuum Co., Germany). According to this test,when the temperature required for oxygen consumption is low, there-oxidation property of oxygen is regarded as excellent. That is,through the oxygen shutting-off test and catalyst re-oxidation test, thecatalyst of the present invention can be proven to have superiornitrogen oxides removal properties even at low temperatures.

Further, the catalyst of the present invention functions to decomposeammonium nitrate formed on the surface thereof at low temperatures.According to the present invention, 1 g of ammonium nitrate is supportedon 10 g of the catalyst of the present invention and then dried. When0.1 g of the sample thus obtained is heated at a rate of 10° C./min inthe presence of 3% oxygen flowing at a rate of 50 cc/min, ammoniumnitrate begins to be decomposed at 173° C.

Moreover, in the case where dioxin is present in the flue gas, theNMO+V/TiO₂ catalyst of the present invention functions to simultaneouslyrealize the SCR of nitrogen oxides and the removal of dioxin. This isbecause the oxidation of dioxin is caused at an active site (V—O—Ti)different from active sites (e.g., V═O and V—OH) required for theremoval of nitrogen oxides over the catalyst of the present invention.Typically, although 0˜500 ppm dioxin is present in the flue gas of theincinerator, it may be removed using the catalyst of the presentinvention.

Therefore, the catalyst of the present invention may be used for SCR ofnitrogen oxides and for removal of dioxin in the temperature range(150˜450° C.) including not only a high temperature range but also a lowtemperature range. In particular, ammonium nitrate formed on the surfaceof the catalyst may be decomposed at low temperatures and thus theinactivation of the catalyst may be prevented at low temperatures. Aswell, the emission of unreacted ammonium can be reduced, hencepreventing self-poisoning thereof and the formation of ammonium sulfate.Thereby, the activity of the catalyst can desirably continue. Also, theuse of the catalyst of the present invention is advantageous becausedioxin may be removed along with nitrogen oxides, thus decreasing thecost of supporting an additional dioxin disposal system, resulting ineconomic benefits.

In the present invention, a fixed-bed reactor for use in evaluating thenitrogen oxide removal performance of the catalyst of the presentinvention for the removal of nitrogen oxides and/or dioxin is shown inFIG. 1. As shown in FIG. 1, the fixed-bed reactor comprises a gas supplypart, a reaction part, and a reactive gas analysis part. The gassupplied into the reactor 10 includes nitrogen 1, oxygen 2, nitrogenmonoxide 3, and ammonia 4 as a reducing agent, the flow rate of each ofwhich is controlled using the mass flow controller (MFC) 6 of a gassupply cylinder. Further, water is supplied in a manner such thatnitrogen is added to the reactor in a state of being contained in waterwhile passing through the aqueous solution. As such, water at apredetermined temperature is circulated using a thermostat outside adouble jacket-shaped bubbler 7 so as to make the supply amount thereofuniform. The gas supply pipe throughout the reactor is preferably madeof stainless steel. The reaction part, which is a continuous flow typefixed-bed reaction device, is manufactured from a quartz pipe 11 havingan inner diameter of 8 mm and a height of 60 cm, and includes glasscotton to fix the catalyst bed 12. The temperature of the reactor isadjusted through a temperature controller 9 using a thermocouple mountedto the upper portion of the fixed bed. Also, the temperature of the gassupply part is measured by mounting a thermocouple having the same shapeto the lower portion of the catalyst layer to determine the differencebetween the temperatures of upper and lower portions of the catalystbed.

In order to analyze the concentrations of the reactant and product,nitrogen monoxide is measured using a non-dispersion type infrared gasanalyzer 14. As such, before being supplied into the gas analyzer, wateris removed using a water remover 13.

Further, to evaluate dioxin removal performance, the device of FIG. 1may be constructed. That is, nitrogen 1′ is supplied into the gas supplypart while passing through an aqueous 1,2-DCB (dichlorobenzene) solution8 having a predetermined concentration, and the reaction part isstructured under the same conditions as above. In the detection part,the emission concentration of 1,2-DCB is measured using a totalhydrocarbon (THC) detector 15. In this case, the 1,2-DCB has a structuresimilar to dioxin, and thus is broadly used as a material for thedecomposition of dioxin.

The nitrogen oxides removal performance test of the denitrificationcatalyst of the present invention is carried out using the device ofFIG. 1. With the intention of maintaining the denitrification catalystuniform, the prepared catalyst is compressed at a pressure of 5000 psiusing a hydraulic press to form a pellet, which is then filtered, thusobtaining a catalyst having a size of 40˜50 mesh. Using thesize-controlled catalyst, the denitrification test in a steady state isperformed through the following procedures.

1) A predetermined amount of catalyst is loaded in the reactor 11.

2) The catalyst is pretreated at 400° C. for 1 hour in an air atmosphereto remove impurities therefrom and attain a uniform oxidation statethereof.

3) The pretreated catalyst is cooled to a desired test temperature andis maintained thereat for 1 hour so as to attain a steady state of thetest temperature.

4) When the test temperature reaches a steady state, a predeterminedamount of known gas is supplied into the reactor and the reaction testprogresses until the concentration of the product is constant, afterwhich that concentration is recorded.

The nitrogen oxides removal performance of the denitrification catalystis represented by nitrogen oxides conversion and is calculated accordingto Equation 1 below:

$\begin{matrix}{{{NO}_{x}\mspace{14mu} {Conversion}\mspace{14mu} (\%)} = {\frac{\begin{matrix}{{{Supply}\mspace{14mu} {Concentration}\mspace{14mu} {of}\mspace{14mu} {NO}_{x}} -} \\{{Emission}\mspace{14mu} {Concentration}\mspace{14mu} {of}\mspace{14mu} {NO}_{x}}\end{matrix}}{{Supply}\mspace{14mu} {Concentration}\mspace{14mu} {of}\mspace{14mu} {NO}_{x}} \times 100}} & {{Equation}\mspace{14mu} 1}\end{matrix}$

The 1,2-DCB removal performance test of the NMO+V/TiO₂ catalyst of thepresent invention is conducted using the device of FIG. 1, throughcontrol of the supply concentration of 1,2-DCB. In addition, the dioxinremoval performance of the catalyst of the present invention isrepresented by 1,2-DCB conversion and is calculated according toEquation 2 below:

$\begin{matrix}{1,{{2 - {D\; C\; B\mspace{14mu} {Conversion}\mspace{14mu} (\%)}} = {\frac{\begin{matrix}{{{Supply}\mspace{14mu} {Concentration}\mspace{14mu} {of}\mspace{14mu} 1},{2 - {D\; C\; B} -}} \\{{{Emission}\mspace{14mu} {Concentration}\mspace{14mu} {of}\mspace{14mu} 1},{2 - {D\; C\; B}}}\end{matrix}}{{{Supply}\mspace{14mu} {Concentration}\mspace{14mu} {of}\mspace{14mu} 1},{2 - {D\; C\; B}}} \times 100}}} & {{Equation}\mspace{14mu} 2}\end{matrix}$

MODE FOR INVENTION

A better understanding of the present invention may be obtained throughthe following examples which are set forth to illustrate, but are not tobe construed as the limit of the present invention.

PREPARATIVE EXAMPLE 1 Preparation of NMO

NMO was used by drying it at 100˜110° C. for 4˜12 hours withoutadditional chemical treatment and then calcining it at 400° C. for 4hours in an air atmosphere. The dried and calcined NMO powder wascompressed at a pressure of 5000 psi to form a pellet, which was thenmilled to an average particle size of 400 μm.

PREPARATIVE EXAMPLE 2 Preparation of V/TiO₂ (N) without Tungsten

2 wt % of ammonium metavanadate was quantified relative to 100 g of atitania support having the properties shown in Table 3 and thendissolved in 150 ml of distilled water heated to 60° C. In such a case,in order to increase the solubility of ammonium metavanadate, oxalicacid was added to set the pH of the solution to 2.5. The solution wasmixed with the titania support and sufficiently stirred, thus preparinga slurry. Subsequently, water was removed at 70° C. using a rotaryvacuum evaporator. The resulting product was further dried at 110° C.for 24 hours and then coarsely milled. The milled catalyst powder wasloaded into a tubular calcination furnace, heated to 400° C. at a rateof 10° C./min with the supply of air at a flow rate of 500 ml/min, andthen calcined at that temperature for 4 hours in an air atmosphere.Below, the V/TiO₂ catalyst having no tungsten supported thereon isreferred to as V/TiO₂ (N).

PREPARATION EXAMPLE 3 Preparation of V/TiO₂ (W) with Tungsten

12.35 g of ammonium tungstate ((NH₄)₂WO₄) was dissolved in 30 ml ofdistilled water, and the resulting solution was heated to about 60° C.to completely dissolve it. After the solution was cooled to roomtemperature, 100 g of titania was added thereto to obtain a slurry. Theslurry was heated to about 70° C. while stirring it to evaporate watertherefrom. After the completion of the evaporation of water, a dryingprocess was conducted at about 120° C. for 24 hours and then acalcination process was conducted at 500° C. for 10 hours in an airatmosphere, thus preparing a tungsten-titania mixed support.Subsequently, the same procedure as in Preparative Example 2 wasconducted, resulting in a V/TiO₂ catalyst having tungsten supportedthereon, which is referred to as V/TiO₂ (W).

EXAMPLE 1

The NMO of Preparative Example 1 was mixed with the V/TiO₂ (N) catalystof Preparative Example 2 through a ball milling process, thus preparinga mixed catalyst. The V/TiO₂ (N) catalyst and NMO were mixed at a weightratio of 10:1 and then ball milled.

EXAMPLE 2

A mixed catalyst was prepared in the same manner as in Example 1, withthe exception that the NMO of Preparative Example 1 and the V/TiO₂ (W)catalyst of Preparative Example 3 were used.

EXAMPLE 3 Nitrogen Oxides Removal Performance

The catalyst (NMO+V/TiO₂(N)) of Example 1, the catalyst (NMO+V/TiO₂(W))of Example 2 and, for comparison with the catalysts of the presentinvention, the catalyst (NMO) of Preparative Example 1, the catalyst(V/TiO₂(N)) of Preparative Example 2 and the catalyst (V/TiO₂(W)) ofPreparative Example 3 were subjected to a nitrogen oxides removalperformance test at a high temperature and a low temperature using thefixed-bed test device of FIG. 1. Then, 200 ppm NO_(x), 15% oxygen and 8%water were supplied, and nitrogen was supplemented such that the totalgas flow rate was 500 ml/min. 0.5 ml of the denitrification catalyst wasloaded and the GHSV was set to 60,000 hr⁻¹. As the reducing agentincluding urea or ammonia, ammonia was used in the present example. Themolar ratio of NH₃/NOx was 1.0, and the reaction temperature wasadjusted to 150˜300° C. The nitrogen oxides removal performance and theemission concentration of unreacted ammonia were measured. The resultsare given in Table 4 below, and FIGS. 2 and 3.

In the results of nitrogen oxides removal performance, as in Table 4 andFIG. 2, the NMO+V/TiO₂(N) catalyst is seen to have higher activity thanthe NMO or V/TiO₂(N) catalyst in a wide temperature range including lowtemperature and high temperature. As such, the NMO has excellentnitrogen oxides removal performance at low temperatures, and theV/TiO₂(N) catalyst has excellent nitrogen oxides removal performance athigh temperatures. Further, the NMO+V/TiO₂(N) catalyst, resulting frommixing the above two catalysts, has activity higher than the nitrogenoxides removal activities of respective catalysts, which is believed tobe because the synergetic effect results from mixing NMO and V/TiO₂ toform composite oxide of Mn—V—TiO₂, functioning to improve the SCR, thusremarkably increasing the activity of the catalyst of removing nitrogenoxides.

TABLE 4 Reaction NMO V/TiO₂(N) NMO + V/TiO₂(N) Temp (° C.) (P. Ex. 1)(P. Ex. 2) (Ex. 2) NO_(x) 300 23.81 90.48 89.52 Removal 250 80.95 87.6288.57 Efficiency 200 85.24 82.86 89.52 (%) 175 74.76 62.86 84.76 15055.71 38.09 58.09 Unreacted 300 0 0 0 Ammonia 250 0 0 0 (ppm) 200 8 3 0175 43 45 6 150 70 110 60

FIG. 3 and Table 4 show the results of emission concentration ofunreacted ammonia, simultaneously obtained in the nitrogen oxidesremoval performance test. As is apparent in the results of Table 4 andFIG. 3, the emission concentration of unreacted ammonia is inverselyproportional to the nitrogen oxides removal efficiency. Particularly,the emission concentration of unreacted ammonia when using theNMO+V/TiO₂(N) catalyst can be confirmed to be lower than that when usingthe NMO or V/TiO₂(N) catalyst. Thus, it has been proven that the mixedcatalyst of the present invention can reduce the emission of unreactedammonia.

In addition, using the V/TiO₂(W) catalyst, the nitrogen oxides removalperformance and the emission concentration of unreacted ammonia weremeasured as above. The results are shown in Table 5 and FIGS. 4 and 5.The results of FIG. 4 are similar to those of FIG. 2. Although thelow-temperature activity of the V/TiO₂(W) catalyst is higher than thatof the V/TiO₂(N) catalyst thanks to the presence of tungsten, it issimilar to that of the catalyst of the present invention, comprisingNMO. Naturally, the catalyst of the present invention comprising NMO hasbetter low-temperature and high-temperature activities, compared to whenNMO is used alone. Thus, the addition of NMO results in improvement ofthe nitrogen oxides removal performance of the catalyst regardless ofwhether the titania support includes tungsten or not. FIG. 5 shows theemission concentration of unreacted ammonia, which is similar to theresult of FIG. 3.

In the case of NMO, nitrogen oxides removal performance is deteriorated,but unreacted ammonia is not detected in the high temperature range of250° C. or more. This means that ammonia added as the reducing agent isoxidized and thus has low usability as a reducing agent. Since theoxidation of ammonia at a high temperature leads to the formation of NOor NO₂, the ammonia reducing agent is further required. The oxidationproperties of the NMO deteriorate the nitrogen oxides removalperformance at high temperatures. However, as in the present invention,the above problems can be overcome by mixing the NMO and the V/TiO₂catalyst. From the results of evaluation of the activity of theNMO+V/TiO₂(W) catalyst, high nitrogen oxide removal efficiency and lowemission of unreacted ammonia at high temperatures can be confirmed.Moreover, as seen in the NMO+V/TiO₂) catalyst, when the NMO and theV/TiO₂ catalyst are mixed, the oxidation of ammonia is prevented.Accordingly, there is provided a synergetic effect exhibiting highnitrogen oxides removal efficiency even in the high temperature range.

TABLE 5 Reaction Temp (° C.) NMO V/TiO₂(W) NMO + V/TiO₂(W) NOx 300 23.8194.76 91.43 Removal 250 80.95 94.29 91.43 Efficiency 200 85.24 87.6289.52 (%) 175 74.76 65.71 80.95 150 55.71 44.76 56.19 Unreacted 300 0 00 Ammonia 250 0 0 0 (ppm) 200 8 8 1 175 43 58 12 150 70 104 70

EXAMPLE 4 Nitrogen Oxides Removal Performance Depending on Mixing Ratioof NMO

The nitrogen oxides removal performance was evaluated depending on theproportion of NMO in the NMO+V/TiO₂ catalyst. The results are given inTable 6 below. As shown in Table 6, when the NMO is used in an amount of5˜30 wt %, nitrogen oxides removal efficiency is increased at lowtemperatures of 250° C. or lower. However, when the NMO is used in anamount of 40 wt %, which exceeds 30 wt %, the removal efficiency israther decreased. Thus, it is preferred that the NMO be used in anamount of about 5˜30 wt %.

TABLE 6 Reaction Temperature (° C.) Amount of NMO (wt %) 400 300 250 200175 150 0 90.0 96.2 96.2 79.0 59.0 34.3 5 90.0 96.8 96.5 81.2 61.0 38.610 90.0 97.1 97.1 82.9 61.9 42.9 20 85.5 95.0 94.0 85.0 63.0 37.0 3084.3 97.1 95.2 77.1 54.3 41.0 40 80.0 94.3 90.5 66.7 47.6 35.2 50 80.590.5 83.8 63.8 50.5 38.1

EXAMPLE 5 Oxygen Shutting-Off Test

In order to evaluate the ability to supply lattice oxygen of theNMO+V/TiO₂ catalyst of the present invention and the conventional V/TiO₂catalyst, the oxygen shutting-off test was conducted. The results aregiven in FIG. 6. Immediately after shutting-off the supply of oxygen,the nitrogen oxides removal efficiency is drastically decreased.However, such removal efficiency does not continuously decrease but ismaintained for a predetermined time period and then decreases again.This is believed to be because the SCR reaction proceeds with theconsumption of the lattice oxygen of the catalyst.

As shown in FIG. 6, the NMO+V/TiO₂ catalyst can maintain the activitythereof for a longer period of time than can the V/TiO₂ catalyst, thanksto the high ability to supply the lattice oxygen thereof. Accordingly,the SCR may more efficiently proceed through oxidation and/or reductionusing the lattice oxygen. The above test was conducted at a lowtemperature of 200° C. At a high temperature, there is no particulardifference in ability between the two catalysts. Therefore, the reasonwhy the nitrogen oxides removal efficiency of the catalyst of thepresent invention is higher at a low temperature is that the ability tosupply the lattice oxygen thereof is excellent.

EXAMPLE 6 Catalyst Re-Oxidation Test

In order to evaluate the oxidation power of the NMO+V/TiO₂ catalyst ofthe present invention and the conventional V/TiO₂ catalyst, are-oxidation test was conducted. The results are shown in FIG. 7. Thetest was carried out in such a manner that oxygen was supplied to thereduced catalyst, and the temperature required for the consumption ofoxygen upon an increase in temperature was measured. In the conventionalV/TiO₂ catalyst, oxygen is consumed at about 335° C., while theNMO+V/TiO₂ catalyst of the present invention consumes oxygen at about325° C., which is about 10° C. lower than the temperature when using theconventional catalyst. Hence, the catalyst of the present invention hasexcellent ability to supply lattice oxygen in Example 5, and also highre-oxidation capability due to gaseous oxygen and thus has superioroxidation and/or reduction to the conventional catalyst. Ultimately,through the above tests, the catalyst of the present invention isconfirmed to have higher activities not only at high temperatures butalso at low temperatures.

In addition, it is noted that the NMO+V/TiO₂ catalyst of the presentinvention is not a simple catalyst mixture. If the two materials aresimply mixed, re-oxidation of oxygen is expected to take place in thespecific regions of NMO and V/TiO₂. That is, if the NMO+V/TiO₂ catalystis a simple mixture, although oxygen is consumed at about 335° C., sucha phenomenon is not observed in FIG. 7. This means that the NMO+V/TiO₂catalyst of the present invention is a novel compound in whichrespective constituent materials are newly combined through a chemicalreaction. That is, the catalyst of the present invention, prepared bysubjecting NMO and V/TiO₂ to wet mixing, drying and then calcining tocause a chemical reaction on the surfaces of two materials so as to forma novel structure, is regarded not as a simple mixture of two materialsbut as a novel catalyst material.

EXAMPLE 7 Ammonium Nitrate Decomposition Performance

The decomposition of ammonium nitrate deposited on the catalyst and thetemperature required for initiating the decomposition may directlyaffect the activity of the SCR catalyst and durability in the lowtemperature range. Hence, the catalyst essentially requires thedecomposition of a salt thereon. Accordingly, poisoning resistance wasevaluated through the ammonium nitrate decomposition test of thecatalyst of the present invention.

In order to measure the decomposition temperature of ammonium nitrate,capable of inactivating the catalyst in the low temperature range, 1 gof ammonium nitrate was artificially supported on 10 g of the NMO+V/TiO₂catalyst of the present invention and then dried. 0.1 g of the catalystwas heated to 300° C. at a rate of 10° C./min without changing thedesorption peak while supplying 3% oxygen at a flow rate of 50 ml/min at110° C., and the decomposition of ammonium nitrate was observed. Theresults are shown in FIG. 8.

As shown in FIG. 8, the NMO+V/TiO₂ catalyst begins to decompose ammoniumnitrate at about 173° C. Thus, it is possible to decompose ammoniumnitrate using the mixed catalyst of the present invention in a lowoperating temperature range of 180° C. or less, thus preventing thepoisoning of the catalyst, resulting in inhibition of the inactivationof the catalyst in the low temperature and also assuring the active siteof the catalyst.

EXAMPLE 8 Dioxin Removal Performance

In order to evaluate the removal performance of dioxin contained in theflue gas using the catalyst of the present invention, 1,2-DCB(dichlorobenzene), having a structure similar to dioxin and being usefulas a material for the decomposition of dioxin, was used. Three tests,including the same SCR test as Example 3 (SCR test), a test for inducingremoval of both nitrogen oxides and 1,2-DCB through simultaneousaddition (SCR+Dioxin test), and a test for evaluating the decompositionperformance through the addition of only 1,2-DCB (Dioxin test), wereconducted.

The SCR test was carried out using 800 ppm NO_(x), 3% oxygen, NH₃/NO_(x)of 1.0, and an amount of catalyst based on GHSV of 10,000 hr⁻¹. TheSCR+Dioxin test was the same as the SCR test, with the exception of theaddition of 300 ppm 1,2-DCB. The Dioxin test was performed using only300 ppm 1,2-DCB and 3% oxygen. As such, the GHSV was set to 10,000 hr⁻¹.

FIG. 9 is a graph showing the nitrogen oxides removal performance uponthe SCR test and the SCR+Dioxin test. Further, upon the SCR+Dioxin testand the Dioxin test, the removal performance of 1,2-DCB is depictedtogether. As shown in FIG. 9, there is no difference in nitrogen oxidesremoval performance, even with the use of 1,2-DCB. In addition, eventhough the SCR reaction progresses together, the removal performance of1,2-DCB makes little difference. This is because the active site of thevanadium/titania catalyst is V—O—Ti for oxidation of 1,2-DCB and also isV═O and V—OH for the SCR reaction. Furthermore, under given conditions,the removal efficiency of 1,2-DCB is 90% or higher. Thus, when the mixedcatalyst of the present invention is used, dioxin in the flue gas doesnot affect the nitrogen oxides removal reaction, and furthermore, may beremoved at the time of the SCR reaction.

INDUSTRIAL APPLICABILITY

As described above, the present invention provides a catalyst preparedby mixing NMO with a V/TiO₂ denitrification catalyst, and a method ofusing the same. According to the present invention, NMO, having highnitrogen oxides removal properties at low temperatures, is mixed withthe V/TiO₂ catalyst, having high nitrogen oxides removal activity athigh temperatures, such that a novel catalyst, having activity ofremoving nitrogen oxides and dioxin greater than when the aboverespective catalysts are used separately, can be obtained. Therefore,the catalyst of the present invention may be used in the field of ahigh-temperature application to which a conventional denitrificationsystem has been applied, and also may be applied to the low temperaturerange where a conventional denitrification catalyst has been impossibleto apply.

During conventional flue gas disposal processes, since the temperatureof the flue gas is low in the rear of the dust collector and/ordesulfurization system, the conventional denitrification catalyst isimpossible to apply. However, the NMO+V/TiO₂ catalyst of the presentinvention can be operated even at low temperatures of 250° C. or less,and hence may be used in the conventional flue gas disposal system. Inaddition, when a conventional denitrification catalyst is applied to therear of a wet desulfurization system, a re-heating process is requiredto form a high-temperature condition. However, in the case of using thecatalyst of the present invention, it can exhibit performance equal toor higher than the conventional catalyst, at a temperature lower than aconventionally used temperature. Thereby, energy used for the re-heatingprocess may be decreased.

That is, when the SCR system using the NMO+V/TiO₂ catalyst of thepresent invention is applied to the conventional flue gas disposalprocess, the application position of the catalyst is less limited, andthus the space may be effectively used. Accordingly, the cost isdecreased without the need for a novel system. Further, the catalyst ofthe present invention may be used in a smaller amount thanks to the highactivity at low temperatures, resulting in decreased system costs andlowered pressure loss of the catalyst bed.

Conventionally, since NMO is decreased with respect to its activity inthe high temperature range, a high-temperature catalyst is required inthe high temperature range. Further, in the operation of a system forthe emission of nitrogen oxides and dioxin, change in the operationthereof and stoppage of the operation thereof take place at temperatureslower than a steady state. Thus, the use of the high-temperaturecatalyst results in drastically decreased removal efficiencies ofnitrogen oxides and dioxin. However, the use of the catalyst of thepresent invention can overcome the above problems.

According to Reaction 1, nitrogen monoxide and ammonia, serving as areducing agent, are supplied at a molar ratio of 1:1. When nitrogenmonoxide and ammonia are supplied in a stoichiometric ratio, that thenitrogen oxides are not completely removed but are discharged indicatesthe emission of unreacted ammonia at the same ratio. Further, unreactedammonia itself is poisonous and is formed into ammonium sulfateaccording to Reactions 6 and 7. Ultimately, the inhibition of unreactedammonia is regarded as very important because it is directly concernedwith the lifetime and activity of the catalyst. As mentioned above, theNMO+V/TiO₂ catalyst of the present invention has high activity even atlow temperatures, and hence it functions to further reduce the emissionof nitrogen oxides and unreacted ammonia, compared to conventionaldenitrification catalysts, leading to prevention of the formation ofammonium sulfate. Generally, in order to decrease the amount ofunreacted ammonia, ammonia is supplied at a ratio of 0.5˜0.8 relative tonitrogen oxides upon actual operation. Particularly, at lowtemperatures, as ammonia is added in a decreased amount, nitrogen oxidesremoval efficiency is lowered. Thus, ammonia should be added at anoptimal ratio in consideration of the unreacted ammonia emission.Therefore, the NMO+V/TiO₂ catalyst of the present invention has highactivity at low temperatures, thus maximizing the amount of ammonia,thereby exhibiting high nitrogen oxides removal performance.

The NMO+V/TiO₂ catalyst of the present invention can decompose ammoniumnitrate formed on the surface thereof at low temperatures, and hence canprevent the inactivation thereof at low temperatures.

Moreover, the NMO+V/TiO₂ catalyst can function to remove dioxin, as wellas nitrogen oxides, contained in flue gas, due to the highlow-temperature activity thereof. That is, it is possible tosimultaneously remove nitrogen oxides and dioxin because the reactionprogresses at the active site for the removal of dioxin, rather than theactive sites for the removal of nitrogen oxides. Thus, there is no needfor an additional dioxin disposal device, decreasing the device cost.

Although the preferred embodiments of the present invention have beendisclosed for illustrative purposes, those skilled in the art willappreciate that various modifications, additions and substitutions arepossible, without departing from the scope and spirit of the inventionas disclosed in the accompanying claims.

1. A vanadium/titania (V/TiO₂)-based catalyst comprising naturalmanganese ore for removing nitrogen oxides and dioxin in a wideoperating temperature range, wherein the vanadium/titania-basedcatalyst, suitable for use in selective catalytic reduction of nitrogenoxides and removal of dioxin contained in flue gas, comprises 0.5˜10 wt% of vanadium.
 2. The vanadium/titania-based catalyst according to claim1, which further comprises 0˜15 wt % of tungsten oxides based on theweight of titania.
 3. The vanadium/titania-based catalyst according toclaim 1, wherein a precursor of the vanadium is ammonium metavanadate orvanadium chloride.
 4. The vanadium/titania-based catalyst according toclaim 1, wherein the natural manganese ore is pyrolusite, composed ofβ-MnO₂.
 5. (canceled)
 6. The vanadium/titania-based catalyst accordingto claim 1, which is applied to a structure selected from the groupconsisting of a metal plate, a metal fiber, a ceramic filter, and ahoneycombed structure.
 7. The vanadium/titania-based catalyst accordingto claim 1, which is applied to an air preheater, or a tube group, aduct, and/or a wall of a boiler.
 8. A method of selective catalyticreduction of nitrogen oxides and removal of dioxin, contained in fluegas, which is conducted at 150˜450° C. at a gas hourly space velocity of1000˜60000 hr⁻¹ in the presence of the catalyst of claim
 1. 9. Themethod according to claim 8, wherein ammonia, which is a reducing agent,is supplied at a molar ratio of NH₃/NO_(x) of 0.6˜1.2 upon the selectivecatalytic reduction of the nitrogen oxides.
 10. The method according toclaim 8, wherein the flue gas comprises 0˜500 ppm dioxin present thereinupon the selective catalytic reduction of the nitrogen oxides.
 11. Thevanadium/titania-based catalyst according to claim 2, which is appliedto a structure selected from the group consisting of a metal plate, ametal fiber, a ceramic filter, and a honeycombed structure.
 12. Thevanadium/titania-based catalyst according to claim 3, which is appliedto a structure selected from the group consisting of a metal plate, ametal fiber, a ceramic filter, and a honeycombed structure.
 13. Thevanadium/titania-based catalyst according to claim 4, which is appliedto a structure selected from the group consisting of a metal plate, ametal fiber, a ceramic filter, and a honeycombed structure.
 14. Thevanadium/titania-based catalyst according to claim 2, which is appliedto an air preheater, or a tube group, a duct, and/or a wall of a boiler.15. The vanadium/titania-based catalyst according to claim 3 which isapplied to an air preheater, or a tube group, a duct, and/or a wall of aboiler.
 16. The vanadium/titania-based catalyst according to claim 4,which is applied to an air preheater, or a tube group, a duct, and/or awall of a boiler.
 17. The method of selective catalytic reduction ofnitrogen oxides and removal of dioxin contained in flue gas, which isconducted at 150˜450° C. at a gas hourly space velocity of 1000˜60000hr⁻¹ in the presence of the catalyst of claim
 2. 18. The method ofselective catalytic reduction of nitrogen oxides and removal of dioxincontained in flue gas, which is conducted at 150˜450° C. at a gas hourlyspace velocity of 1000˜60000 hr⁻¹ in the presence of the catalyst ofclaim
 3. 19. The method of selective catalytic reduction of nitrogenoxides and removal of dioxin contained in flue gas, which is conductedat 150˜450° C. at a gas hourly space velocity of 1000˜60000 hr⁻¹ in thepresence of the catalyst of claim 4.